DE3148992C2 - - Google Patents

Description

The invention relates to a self-converging deflection yoke for a picture tube with the in the preamble of claim 1 specified features.

A color television picture tube produces three electron beams, which on special color-emitting fluorescent elements hitting a screen. A mon on the picture tube The deflection yoke creates a magnet that changes over time fields near the electron beams so that they Generation of a grid horizontally and vertically over the Screen distracted. It is desirable that everyone Beam only a single fluorescent element of a special Color emission mapping meets. The extent to which that the case determines the purity of the grid. It is also important that the rays at all points of the picture the screen hitting the screen close together, that the rays converge on the screen.

Most color picture tubes generate electron beams in one of two configurations, either in delta Configuration or in a horizontal one level lying pattern. Requires tubes with a delta beam system a dynamic convergence circuit so that the rays converge on distraction. Inline tubes allow each  but the construction of a deflection yoke, which the Electron beams at all points on the tube screen lets converge without a dynamic conver limit switching would be necessary.

This self-converging yoke for inline tubes the electron beam convergence by the nature of the Un uniformity of the deflection field by a special configuration of the deflection coils. It it is known that the horizontal deflection coils as a whole ge see must create a pillow-shaped field and that the Vertical deflection coils a total of a barrel-shaped field have to create in order to obtain beam convergence. It are also techniques for winding deflection yoke coils knows what the desired field irregularities he give.

Deflection yokes can have coils which are toroidal, saddle shaped or in combination of both types of winding around one magnetically permeable core are wound. A custom Lich yoke uses saddle-shaped horizontal coils and toroidal vertical coils. Both the saddle spools as the toroid coils also generate external fields on the sides and at the back of the yoke in addition to the main ab steering fields that are created in the inner area of the yoke the. The external field on the back of the yoke, that of a Toroidal coil is generated, however, is of the order of magnitude five times larger than the exter produced by a saddle coil ne field. The presence of these external fields on the The back of the yoke can hold the electron beams inside the Focus area of the beam system undesirably affected sen. A premature beam deflection can occur noticeable defocusing of the rays on some Of the screen. At a Yoke with toroidal vertical coils and saddle shaped Horizontal coils give the external vertical field the strongest most undesirable effects.  

With self-converging yokes there is an additional one Problem on: Although for electron beam convergence barrel-shaped vertical field is necessary, results in a barrel shaped field a stronger deflection of the outer rays than the center beam, and this leads to vertical coma which the height of the center beam grid is smaller than for the External beam grid is. It is known that vertical coma error at the beam entry end or the back of the Yokes are very dependent on field uniformity. The barrel-shaped outer field of the vertical deflection coils carries therefore significantly to the vertical coma error.

It is from the magazine for correcting the deflection fields of a deflection yoke of the type mentioned at the beginning "Funk-Technik" No. 23 (1976) pages 764 to 767 known in Precision inline tubes, magnetic shielding and control elements elements to be installed, which are the deflection fields at the rear weaken or strengthen the deflection system, so that the mitt ller beam receives relatively more deflection than the two outer rays.

From US-PS 34 30 169 is the use of a magnetic permeable ring around the tube neck in the focusing range of the Beam system known for short-circuiting the outer field. However, this shorting can make the deflection field undesirable weaken, so that the then lower beam deflection Increase the deflection must be compensated.

Based on the aforementioned US patent, the Invention based on the object in an inline color image shield the beam generating system against the defocusing interference fields on the back of the yoke at the same to achieve early coma correction. This task is accomplished by solved the features specified in claim 1.

Further developments of the invention are in the subclaims featured.  

The correction device according to the invention contains a magnetically permeable ring, which is on the inside of the yoke half of the outer yoke field is arranged around the from the outer to divert their field originating river into the ring while doing so the non-uniform field to influence the distraction to modify the three rays, and in this ring is one Slit formed a small fraction of the ring diameter to the magnetic flux through the Interrupt ring. This will create the beam system not only against disturbing magnetic fields on the back shielded side of the deflection yoke, which defocusing would work, but the ring immediately causes a coma correction in which the central jet is less than that in the outside rays are deflected.  

An embodiment of the invention will be explained with reference to the drawing. It shows

Figure 1 is a sectional view of a color image display system seen from above to illustrate the lateral mutual relationships between the outer field of the deflection yoke and the electron beam system of the picture tube.

Fig. 2 is a rear sectional view of the system of Fig. 1 illustrating the outer field of the vertical deflection coil;

Fig. 3 is a plan view of a color television display system illustrating a correction device according to the invention; and

FIG. 4 shows a rear cross section through the system according to FIG. 3 to illustrate a feature of the correction device.

Figs. 1 and 2 show a color television display system comprising a picture tube 10 having a neck 11, a cone 12 and a phosphor screen, not shown, attached to the said neck is located 11 opposite the end of the picture tube. Inside the neck 11 is an electron beam system 13 , which generates, accelerates and focuses three electron beams. In the system of FIG. 1, the three electron beams lie horizontally in one plane. On the picture tube 10 , in the area where the neck 11 merges into the cone 12 , a deflection yoke 14 is mounted, which comprises a pair of saddle-shaped wound Hori zontalablenkspulen and a pair shown in Fig. 2 toroidal around a magnetically permeable core 16 ge vertical deflection coils shown 15 has. Horizontal and vertical deflection coils are separated by a plastic insulator 17 . On the back of the yoke 14 , a mounting plate 18 is attached to the insulator 17 , which can have a clamp so that the yoke 14 can be fastened to the picture tube 10 after its position has been correctly adjusted.

Fig. 1 shows the external field generated by the vertical deflection coils 15 of the yoke 14 based on field lines 20.. It is known that the external field is present in an area in which part of the electron beam system 13 is located. This field leads to a slight deflection of the beams within the electron beam system, which can lead to a deterioration of the beam focusing. With a desirably short picture tube, this problem becomes even more serious because the electron beam system sits close to the back of the deflection yoke and therefore lies within the outer fields of the yoke.

Fig. 2 shows a rear view of the yoke. The field lines 20 of the outer field are drawn in a barrel shape and represent the outer field of the vertical deflection coils. The barrel shape of the field results from the field expansion as a result of mutual repulsion of the field lines between the concentrated field ends. Since the outer vertical deflection field of the toroid coils is on the order of five times larger than the outer horizontal deflection field of the saddle coils, the outer vertical field has a much greater influence on the electron beams than the outer horizontal field. Even if the external field of the horizontal saddle coils is not completely insignificant, it does not have a great influence on the coils. Therefore, only the outer vertical field is shown in FIG. 2.

In addition to its effect on beam focusing, the outer vertical field shown in Fig. 2 can also lead to a problem resulting from the property of the non-uniformity of the shape of the field. The barrel-shaped outer vertical field exerts a greater deflecting force on the outer electron beams 21 and 22 than on the center beam 23 , since the field lines 20 are least concentrated along the vertical axis through the picture tube. This higher vertical deflection of the outer beams 21 and 22 with respect to the central beam 23 leads to a vertical coma in which the grid height of the central beam is reduced with respect to the external beams.

FIGS. 3 and 4 show a color television display system comprising a picture tube 110 and a deflection yoke 114 similar to the illustration of FIG. 1. toroidally wound Verti kalablenkspulen 115 are the same as the plastic insulator 117 shown. A correction element 24 sits on the picture tube neck in the vicinity of the focusing region of the beam system. It consists of a magnetically permeable material and therefore forms a path for the magnetic flux low resistance as air. Part of the flow 120 of the outer field is therefore directed into the correction member 24 , as shown in FIG. 3. By deriving this flow from the outer deflection fields in the correction member 24 , the flow remaining within the tube neck is less con centered. The decrease in the flux concentration leads to less interaction between the external field and the electron beams, and thus there is a smaller coma error. The coma error is also reduced in that the permeable correction element 24 places a limit on the external field, in particular on the top and bottom of the tube neck, as a result of which the field lines within the tube neck are somewhat flattened. This flattening makes the field less barrel-shaped, and the coma error is reduced.

The correction member 24 includes a pair of semicircular ring segments 25 and 26 which are separated by slots 27 and 28 on the top and bottom of the correction member 24 ge. The separation distances or slot widths are a small fraction of the diameter of the ring surrounding the tube neck, but they are important for the following reasons. The segment separation ensures an interruption of the path of low magnetic resistance of the correction segments 25 and 26 , so that the entire magnetic resistance was slightly increased. This increase in magnetic resistance results in less flux being diverted through the correction member 24 than would be the case if the correction member were a continuous ring. Although removal of the outer field from the beam focusing area is desired, the outer deflection field contributes to deflecting the beams at other locations, so that the deflection required by the main deflection fields, and thus their performance, is reduced. If the correction element 24 were a continuous ring, then a considerable portion of the desired external field would be derived into the correction element 24 , and one would receive a lower beam deflection, for the compensation of which an increase in the deflection power would be necessary. The separation between the segments 25 and 26 allows a sufficient flow deflection from the outer fields into the correction member 24 to improve beam focusing and to reduce the coma error, but precludes the derivation of an unnecessary amount of flow, which leads to an undesirable reduction in the deflection would lead.

The separation points between the segments run in the vertical axis of the picture tube, so that they represent an interruption in the path of the vertical flow. This orientation results from the relative difference between the outer horizontal and vertical fields, as has already been explained. The segments interrupt the horizontal flow somewhat, which would otherwise circulate through the correction element 24 .

Claims (6)

1. Self-converging deflection yoke for a picture tube, the beam generating system ( 13 ) provides three horizontally in one plane electron beams ( 21 , 22 , 23 ), with horizontal and vertical deflection coils ( 15 , 115 ), which have non-uniform fields for deflecting and converging the beams generate, namely a main deflection field and an outer field ( 20 , 120 ), and with a vertical coma correction device, characterized in that the vertical coma correction device from a distance from the back of the yoke ( 14 ) around the picture tube neck ( 11 ) and inside the outer field ( 20 , 120 ) in the focusing area of the beam generating system ( 13 ) is arranged magnetically permeable ring ( 24 ), and in that in the ring a slot ( 27 , 28 ) is formed which the magnetic flux flowing through the ring interrupts, and the slot width is a small fraction of the ring diameter. 2. deflection yoke according to claim 1, characterized in that the slot ( 27 ) in the upper part of the ring ( 24 ) along the vertical axis of the yoke ( 14 ) and a second slot ( 28 ) is arranged in the lower part of the ring along the vertical axis of the yoke . 3. deflection yoke according to claim 1 or 2, characterized in that the horizontal deflection coils are saddle-shaped ge and that the vertical deflection coils ( 15 , 115 ) are wound toroidally. 4. deflection yoke according to claim 2 or 3, characterized in that the slots ( 27 , 28 ) are dimensioned so wide that they determine the magnetic resistance of the flow path through the ring ( 24 ). 5. deflection yoke according to any one of the preceding claims, characterized in that the outer field ( 20 , 120 ) has a barrel-shaped cross section and that the ring ( 24 ) reduces the field strength of the barrel-shaped field ver for correcting vertical coma errors between the electron beams. 6. deflection yoke according to claim 5, characterized in that the ring ( 24 ) deflects part of the outer field ( 20 ) away from the electron beams.